The Metabolism of Carbaryl in the Rat, Guinea Pig, and Man

M E T A B O L I C FATE: J. B. K N A A K , MARILYN J. TALLANT, W. J. BARTLEY,' and 1. J. SULLIVAN

The Metabolism of Carbaryl in the Rat, Guinea Pig, and Man

Mellon Institute, Pittsburgh, Pa.

The metabolic fate of methyl-C14, ~arbonyI-C'~, and naphthyl-C14carbaryl in the rat and guinea pig was investigated. The over-all recovery of the naphthyl, carbonyl, and methyl label was, respectively, 95, 99, and 91% of dose. Tissue residues (2 to 3% of dose) were found only in the case of methyl-labeled carbaryl. The metabolites identified were 4-( methylcarlbamoyloxy)- 1 -naphthyl glucuronide, 1 -naphthyl glucuronide, 4-(methylcarbamoyloxy)-1-naphthyl sulfate, and 1 -naphthyl sulfate. Evidence i s presented for the possible direct conjugation of carbaryl with glucuronic acid to form 1 -naphthyl methyl carbamate IV-glucuronide and 1 -naphthyl methylimidocarbonate 0-glucuronide. The assay of carbaryl, carbaryl derivatives, and metabolites in water b y fluorometry was investigated in conjunction with C14 chromatographic studies and the method applied to the analysis of urines from men exposed to carbaryl dust. The only detectable metabolites present were 1 -naphthyl glucuronide and sulfate.

T

ME2TABOLIS\f of carbaryl. 1naphthyl .\--methylcarbarnate, has been investigated in isolated systems (5) and in the intact animal (.3> #). These studies indicate that carbaryl is hydroxylated or hydrolyzed in the animal to 4- or 5-hydroxy-1-naphthyl methylcarbamate, 1 -naphthyl h>-droxymethylcarbamate. and 1-naphthol prior to the formation and excretion of their Xvater-soluble c0n.jugate.r. 7 h e urinary conjugates of theye metabolites have not been separated and identified. In the p r e v n t study the: metabolism of c a r b x y l has been re-examined and the urinary conjugates have been determined by chromatographic methods. HE

Methods Chemicals. Carbaryl-methyl-C'1 was prepared by reaction of freshly distilled naphthyl chloroformate (2.6 mmoles.) dissolved in 3.0 ml. of chloroform with methyl-C14 amine-HC1 (2.3 mmoles; 0.28 mc. per mmole. Radiochemical Co.. Chicago. Ill.) dissolved in 2.0 ml. of \cater in a sealed reaction tube in the presence of K.'CO,j (5.5 mmoles) at room temperature. T h e tube was shaken 4 hours. then opened and the aqueous phase extracted with chloroform. 'l'he chloroform phases were combined. dried using anhydrous Na2SO,. and evaporated onto 5.0 grams of F l o r i d . The carbaryl-Florisil mixture \vas added to the top of a 2.5- X 35-cm. column containing 0 ' grams of F l o r i d and carbar>-l eluted acrording to the method of Krishna. Ilorough, and Casida (12) to !-ield 0.416 gram of lvhite. crystalline carbaryl. Van Slyke \vet combustion of the labeled. material indicated a specific activity of 0.231 mc. per mmole for a total activity of 0.481 mc. Present address. L-nion Carbide Olefins Di\ ision. South Charleston. \V. Va.

Isotopic dilution of 1.28 mg. of the radioactive product with 1.0002 grams of nonlabeled carbaryl followed by two recrystallizations from toluene yielded a new specific activity of 0.000295 mc. per mmole. This corresponded to a radiopurity of 100 & 1.5yc. Carbaryl-l-naphthyl-l-C14 (0.2 mc. per mmole) was prepared from 1naphthol and methyl isocyanate in the presence of pyridine according to the method of Skraba and Young ( 7 1 ) . The 1-naphthol-1-C14 \vas purchased from Nuclear-Chicago Corp., Chicago. Ill. Radioactive 1-naphthyl sulfate was prepared by treating 1-naphthol-1-C" (0.6 mmole, 0.115 mc. per mmole) dissolved in 0.3 ml. of dimethylaniline dropwise \vith chlorosulfonic acid (0.72 mmole) in the cold according to the method of Feigenbaum and Neuberg ( 6 ) . The reaction tube was tightly stoppered and agitated overnight at room temperature on a slowly revolving shaft. The viscous, light brown reaction mixture \vas treated with saturated aqueous K O H until slightly basic. The resultant xchite precipitate \vas stirred \vel1 Lvith a spatula to ensure complete neutralization. after which the salt \vas triturated carefully with six 3.0-ml. portions of anhydrous ether. The residual solid \cas dried in vacuo a t 60" C. for approximately 30 hours. yielding 0.244 gram of crude potassium 1-naphthyl-1-CI4 sulfate \cith a specific activity of 0.074 mc. per mmole. A similarly prepared and repurified sample of nonradioactive sulfate exhibited the follo\cing analysis : Analysis Calcd. for ClJHiSO4K: C, 45.8; H, 2.7; S? 12.2. F o u n d : C, 45.7; H j 2.8; S, 12.1. T h e nonlabeled 4- and 5-hydroxy-lnaphthyl methylcarbamates (4- and 5hydroxy-carbaryl) were prepared by reaction of the corresponding naphthalenediol (0.1 mole) with 8.0 ml. of methyl isocyanate, 2 drops of dibutyltin diacetate. and 100 ml. of dry acetone in a pressure bottle overnight a t room temVOL.

perature. The reaction yielded mixtures of the corresponding biscarbamate. monocarbamate, and unreacted diol. The biscarbamates were relatively insoluble in acetone and were removed by filtration. The crude 4-hydroxycarbaryl \vas crystallized from boiling toluene to yield 14.2 grams (657,) of slightly impure product, m.p. 158-61' C. An analytical sample was obtained as colorless flat needles from benzene: m.p. 165-66" C. Seventeen grams of crude 5-hydroxy-carbaryl were obtained upon evaporation of the acetone filtrate. Several reprecipitations from ethyl acetate by dilution u i t h hexane followed by repeated crystallization from toluene gave 4.0 grams of off-white crystals. m.p. 166-67' C. from toluene. Analysis Calcd. for C1."1INOI: C. 66.35; H , 5.10; N: 6.45. Found: 4hydroxy- 1-naphthyl methylcar hamate C. 66.52; H: 5.04; N, 6.29. 5-Hydroxy-lnaphthyl methylcarbamate C, 66.21 ; H: 5.15; N, 6.45. Nonlabeled .\--hydroxy-1-naphthyl methyl carbamate (.\'-hydroxycarbaryl) was prepared from the chloroformate of 1-naphthol and hydroxyl amine hydrochloride according to the procedure of Dorough and Casida (5). Carbaryl-carbonyl-C" with a specific activity of 1.6 mc. per mmole was purchased from Yolk Radiochemical Co.. Chicago, Ill.. and was shown by thin-layer chromatography (5) and radioautography to be 987' carbaryl. Sonlabeled carbaryl and 1-naphthol were supplied by Union Carbide Olefins Division, South Charleston, \\:, Va. Naphthyl glucuronide was purchased from Bios Laboratories, Inc., New York, N. Y. Uridine diphosphoglucuronide was purchased from Calbiochem, Los Angeles, Calif., and uniformly labeled uridine diphosphoglucuronic C" acid was purchased from Xew England Nuclear Corp., Boston, Mass.

13, N O . 6, N 0 V . - D E C .

1965

537

Excretion of Carbaryl-Cl4. Naphthyl-Cl4, methyl-Cl4. and carbonyl-C'd carbaryl dissolved in polyethylene glycol 400 were individually administered (orally) to rats (four animals per labeled compound) (1.28 to 3.9 mg. of carbaryl in 500 mg. of glycol) using the weighed syringe technique. Male rats (Carworth Farms-Elias stock) \veighing approximately 150 grams were used and maintained on a commercial synthetic diet (Nutritional Biochemicals Corp.. Cleveland, Ohio) containing 107, alphacel, 4% vegetable oil, 277, vitamin-free casein. 407, sucrose. 47, salt mixture, and vitamins in order to facilitate the collection of fecal material. The animals were individually housed in glass metabolism cages which permitted the separation and simultaneous collection of urine, feces, and respiratory CO?. The daily urine and fecal samples from each animal ivere separately analyzed for Cli over a 7-day period. Respiratory COn from each animal was trapped and analyzed for C14 over a 4-day period. After 7 days, the animals \vere sacrificed and their gastrointestinal tracts removed. 'The gastrointestinal tracts were frozen and stored separately from the carcasses and remaining organs to aivait analysis for C14. Methods for C14 Analysis. A Nuclear-Chicago scintillation spectrometer. Model 725, operated a t 32' F. was used to detect and measure CI4. All counts \vere corrected to 10070 efficiency values based on a standard curve of channel ratio us. efficiency. For counting purposes, urines \\ere diluted 1 to 10 with tvater and 1.O ml. of the diluted sample was added to 18.0 ml. of a scintillation mixture consisting of 1 part of xylene: 3 parts of dioxane, and 3 parts of methyl Cellosolve (methoxy'v.) 2,s-diphenethanol) with 1.0y0 (w., yloxazole (PPO). 0.057, (w.,'v.) 1.4 bis-2-(5-phenyloxazolyl) benzene (POPOP): and 8.07' (\\. ,'v.) naphthalene (2). Dilution was required to reduce quench and increase sampling accuracy. The fecal samples were dried in a vacuum oven a t 60' C. and ground, and 0.5-gram quantities were weighed into cellulose bags made from dialysis tubing (70). One-half milliliter of a lOy0 (\v., 'v.) sucrose solution was added, the sample thoroughly wetted, and the bag closed and dried in a n oven at 60' C. The sucrose served as a binder for the po\vdered sample. A Parr doublevalved oxygen bomb was utilized to combust the samples (73). The CL402 produced was bubbled through two absorption traps ( 9 ) over a 30-minute period. Each trap contained 15.0 ml. of 207c ethanolamine in methyl Cellosolve (8). Two milliliters of the trapping reagent were used for counting purposes along with 18.0 ml. of the scintillation mixture. Each trap was assayed separately for radioactivity. The gastrointestinal tracts, carcasses. and remaining organs were frozen and co-ground with dry ice in a Model ED-5 Thomas-Wiley mill. This was facilitated by constructing a Masonite box around the body of the mill and filling i t with dry ice. The ground tissue was dried at 60' C. in a vacuum oven, re-

538

J. A G R . F O O D C H E M .

ground, and prepared for scintillation counting. as were the fecal samples. For the collection of respiratory CliOY. a modification of the metabolism cage sold by Delmar Scientific Laboratories, Maywood, Ill., was used. The second absorber containing Drierite and Ascarite removed the moisture and CO:! given off by the animal. Slight negative pressure was employed on the outlet side of the second gas absorber to produce a flow of air through the system of 1 .O liter per minute. The flow rate (from high to low pressure) was controlled through the use of a differential low flow controller (Model 64BUL. Moore Products Co.. Pittsburgh. Pa.) and flow gage. In operation, 50 grams of 8- to 20-mesh Ascarite were weighed into the CO. absorber and mixed with 15.0 grams of 10- to 30-mesh Chromosorb P (JohnsManville). At the end of a 24-hour period, the Ascarite-Chromosorb P mixture was removed and reweighed and the difference in \veight attributed to the COU plus moisture absorbed. Because small quantities of moisture Lvere absorbed, it became necessary to dry the mixture to constant \\eight in an oven prior to obtaining a \veight for CO?. A weighed amount of Ascarite plus Chromosorb P containing 3.0 grams of C O Uwas placed in the bottom of a 2.0liter flask. The flask was fitted so that 5.O.Y H&O$ could be added. the contents were stirred. and the liberated C O ? was flushed xvith nitrogen into a series of tlvo absorption traps ( 9 ) . each of which contained 15.0 ml. of a 2 to 1 mixture of methyl Cellosolve and ethanolamine as trapping reagents. Two milliliters of the 2 to 1 mixture ivere then placed in a counting vial along Ivith 18.0 ml. of the scintillation mixture. The recovery of C l 4 0 ?from Ascarite was determined to be 7370 by the direct liberation of a kno\vn quantity of C ' " 0 ~ trapped on 22.0 grams of Ascarite. The Cl40. was obtained by the complete combustion of 100 mg. of benzoic-C14 acid (0.39 mc. per mmole) in a Parr oxygen bomb. Urinary Metabolites of Carbaryl-C" and Derivatives in the Rat and Guinea Pig. Naphthyl-C". methyl-Cl4. and carbonyl-Cl4 carbaryl (3.0 mg. in 300 mg. of polyethylene glycol 400) were individually administered (intraperitoneal) to each of three 150-gram male rats. At this dose level and route of administration 73, 47, and 48% of the naphthyI-Cl4; meth~1-C'~. and carbonylC14 carbaryl equivalents, respectively, \\ere excreted in pooled 24-hour urines. Naphthyl-C14 and methyl-CL4carbaryl 3.0 mg. in 300 mg. of polyethylene glycol 400, were individually administered (I.P.) to each of three 200-gram guinea pigs. Eighty-five per cent of the count administered was recovered in 24-hour pooled urines. For identification of the major metabolites of carbaryl-C14. l-naphthol-C14 (10 mg.), 4-hydroxycarbaryl (3.0 mg.)? and ,Y-hydroxycarbaryl (3.0 mg.) were administered individually (I.P.) to each of three 150-gram male rats. The compounds were administered dissolved in a minimum volume of polyethylene glycol 400. The count present in 24-hour

pooled urines from 1-naphthol-C"treated animals accounted for 857, of the dose. TLventy-four-hour urines were pooled by compound and used in the chromatographic studies. Twenty-four-hour control urines were obtained from nontreated animals. For chromatographic purposes the pooled 24-hour urines were adjusted to pH 7.5 with 1.Y HC1 or S a O H and 2.0 ml. of urine containing 0.2 to 1 . 7 mg. of carbaryl-C14. 1-naphthol-CL4.4-hydroxycarbaryl, or .\--hydroxycarbaryl equivalents were chromatographed on diethylaminoethyl-cellulose (DEAE-cellulose). Urinary Metabolites of Carbaryl in Human Urine Specimens. Twentyfour-hour urine specimens Lvere obtained by the Medical Department. Cnion Carbide Corp.. from men exposed to carbaryl dust during normal packaging operations a t the institute plant. Trventyfour-hour control specimens jvere obtained from the same men 72 hours after last exposure to carbaryl. For chromatographic purposes the urines were adjusted to pH 7.5 \vith 1.V NaOH and 2.0 ml. of urine \vere chromatographed on DE.4E-cellulose. Metabolism of Carbaryl-Cl4 and Derivatives by Liver Preparations. Guinea pig and rat liver microsomes were prepared according to the method of Smith and Breuer (77) for rabbit liver microsomes. The microsomal fractions were suspended in 7.0 and 15.0 ml. of O.lj4.M KCI. respectively. for the rat and guinea pig, One milliliter of this suspension corresponded to 1.0 gram of fresh liver. The rat and guinea pig liver homogenates (ljYc LV. v.) \\-ere prepared in 0.25.M sucrose using a Teflon-glass Potter-Elvehjem homogenizer at 4" C. .4 typical incubation mixture consisted of 1.0 mg. of l-naphthol-C14, carbaryl-naphthyl-C14. carbaryl-methyl-C14, 4-hydroxycarbaryl. or .\--hydroxycarbaryl dissolved in 0.2.ml. of polyethylene glycol 400; 1.0mg. of uridine diphosphoglucuronic acid (L-DPGA) or uridine diphosphoglucuronic-C1' acid (0.001 pc. per mmole); 1.0 ml. of 0.1.V phosphate buffer. pH 8.0; and 1.0 ml. of the microsomal suspension or liver homogenate. I n two studies involving carbarylnaphthyl-C" (Table I I ) ? 1.0 mg. of reduced nicotinamide-adenine dinucleotide phosphate (NADPH?) \vas added in addition to UDPGX. .After incubation the mixture was extracted with diethyl ether (3 X 5 ml.) to remove organicsoluble materials ( 1-naphthol, carbaryl). The protein was removed from the reaction mixture by precipitation Lvith ethanol. One milliliter of the ethanolwater solution and the ether phase were individually analyzed for CI4. The ethanol-water solution \vas rotary evaporated to a volume of 2.0 ml. and the metabolites in solution ivere chromatographed on DEAE-cellulose. The ether phase was rotary e v a p r a t e d to a volume of 0.5 ml.. and the ethersolubles were chromatographed on thinlayer plates of silica gel G (7). Radioactive materials on the plate were located by removing 1.O-cm. squares from the plate for direct counting in scintillation vials. Identification \vas accomplished by comparing the R, values of the radioactive

material \vith that of norilabeled carbaryl, 1-naphthol, and 4-hydroxycarbaryl chromatographed simultaneously on the plate. The nonradioactive compounds were located using an aqueous spray reagent composed of 5.0 grams of K 2 C r r 0 7 in 100 ml. of 40y0 (v., v.) H r S 0 4 . Ion Exchange Chromatography of Urinary and Microsomal Metabolites of Carbaryl-Cl4 and Derivatives, T h e urinary and microsomal metabolites were applied to the top of a 1.5- X 24.0cm. column of DEL4E-celluloseprepared for chromatography in the following manner. Six grams of DEAE-cellulose (Nutritional Biochemicals Corp., Cleveland, Ohio) in 200 ml. of 0.01M tris (hydroxymethyl)aminomethane-HC1 (tris-HCI), pH 7.5 were poured batchwise into a chromatographic column fitted with a fritted glass disk. T h e cellulose was allowed to settle under flow conditions produced by gravity and was further compacted by air pressure a t 10 p s i . This process was repeated until the column \\-as filled to a height of 24.0 cm. Prior to chromarography the packed cellulose was warhed with 1 .0 liter of the starting buffer to ensure pH equilibration. The metabolites \vere eluted from the column by using t\vo linear gradients as indicated in Figure 2. Volumes of 300 ml. were used in both the mixing chamber and the reservoir of the gradient device. The gradient devic,: used in this study consisted of t\co polyethylene cylinders connected through th'e bottom with 5-mm. i.d. tubing. The gradient was taken off through the bottom of the mixing chamber. The f l o ~ vr.ate \cas established using an all-Teflon microbello\vs pump (Rescarch Appliance Co., Allison Park. P a . ) . T\co hundred and eighty 4-ml. fractions Lvere collected and 1.0 ml. per fraction \cas analyzed for C14 by liquid scintillation techniques. T h e remaining

3.0 ml. were analyzed in a n AmincoBowman spectrophotofluororneter using a xenon lamp (American Instrument Co.. part 416-992). All fractions were read at a fluorescence excitation setting of 285 mp and a fluorescence emission setting of 335 mp. Fractions 1 to 80 Lvere made basic with 1 to 2 drops of 5.V h-aOH and allowed to stand overnight prior to reanalysis at a fluorescence excitation setting of 330 mp and fluorescence emission setting of 465 mp. When carbon-14 was not used. only an analysis by fluorescence kcas made. Results

Excretion of Carbaryl-Cld. T h e excretion of an orally administered dose of l-naphthy1-Cl4. methyl-C", and carb0ny1-C'~carbaryl equivalents by the rat is given in Figure 1 for three studies in-

Table I .

volving four animals per study. T h e average per cent recovered for the three labeled samples over a 7-day period \\-as 947,. T h e excretion of carbaryl is essentially complete by the end of three days. Naphthyl-labeled carbaryl was not oxidized to Cl402 in the rat while methyl- and carbonyl-labeled carbaryl gave rise to 11 and 32% of the dose, respectively. as C'and carbonyl-C'? carbaryl in the first day urine of the rat, and metabolites of 11aphthy1-C'~ and methyl-C14 carbaryl in the guinea pig. Recoveries off the ion exchange column varied from 90 to 95% of the C14applied. T7ariation \vas primarily due to difficulties in pipetting an accurately measured rample onto the column. Metabolites in peak A (Table I) \\-ere not retained by DEAE-cellulose. l h e y \\-ere eluted in one void volume and \\-ere considered to be neutrals or nonacidic metabolites. The neutrals were continuously extracted from tris buffer, pH 7.5.with dieth>-l ether over a 24-hour period. Diethyl ether extracted 857c of the C14 neutrals excreted by animals administered carbar)-l-naphthyl-C14 and 30% from animals receiving carbarylmethy1-Cl4. Re-extraction of the naphthyl- and meth>-l-labeled neutrals a t pH 2.0 recovered an additional 8.7 and 3.07, respectively. of the total. The neutrals extracted at pH 7.5 were chromatographed on thin-layer chromatoplates of silica gel G (5). The R j value for 80% of the methyl-labeled CI4 metabolites \\-as 0.1, ivhile 63Yc of the naphthyl-C14 metabolites possessed the same R, value. No free carbaryl. 4-hydroxycarbaryl. 5-hydroxycarbaryl, or 1-naphthol could be found. Metabolites B. C. D , E. F: and H were found to possess the intact C--0-C(0) N-C structure (Table I). while metabolites G and I were detected only ivith labeled naphthol. Metabolite B \vas found in the pH 8.0 urines of guinea Figs administered methyl- and naphthyl-labeled carbaryl: but was not found in the p H 6.0 urines of rats administered methyl-, carbonyl-, and naphthyl-labeled carbaryl (Table I ) . Storage of the rat urines a t pH 7.5 for 4 months (0' C.) brought about the partial conversion (50%) of metabolite D to metabolite B !\-ithour the loss of the C0-C(0)N-C structure. The rate and optimal conditions for conversion were not investigated. Metabolite E \vas found only in the urine of guinea pigs administered naphthyl- and methyllabeled carbaryl, although small undetected amounts may be excreted by the rat. .4ccording to Terriere, Boose, and Roubal (76)>1-naphthol is excreted by the rat as 1-naphthyl glucuronide and

540

J. A G R . F O O D C H E M .

Table II.

Metabolism of Carbaryl-Naphthyl-C14 b y liver Preparations

% of Metabolites", l

% of

Metabolites",

Total Water-Soluble C i 4 11 Ill lV

v ...

Carbaryla 4s W a t e r -

1

Salubles

..

83.0 8 . 1 2 . 9

.

985 0 0

1 2

6 5

8 0

175 3 0 11 0 5.0 10.0

920 97 5 100 0 98.5 100.0

0 0 0 0 0 0 0.0 0.0

0 0 0 0 0.0 0.0

Kat liver homogenate.

Fluorescence Characteristics of Carbaryl, Derivatives and Metabolites Excitation M a x . , MI1

Compound

~

Total Ether-Soluble C14 VI VlI Vlll lX

RLM. NADPH?* ... ... .. ... 6.0 RLM. N A D P H ~ , UDPG.1 268 0 0 6 0 182 490 0 3 GPLM, NADPH*, UDPGAc 304 0 0 0 0 202 491 0 0 0 0 57 0 2 5 0 0 00 RLM.UDPG.l 43 0 0 0 92 0 0 0 0 0 00 GPLM.UDPG-\ 8 0 RLH, UDPGXd 36.0 13.0 0 . 0 0 . 0 51.0 1 . 5 1 . 0 98.0 0 . 0 GPLH, UDPGA' 1.0 0.0 0.0 a I. Unidentified water-soluble neutrals. 11. 1-Naphthyl methylimidocarbonate 0-glucuronide 111. Unidentified metabolite IV. 4-( Methylcarbamoy1oxy)-1-naphthyl glucuronide V. 1-Naphthyl glucuronide VI. 1-Naphthol VII. Carbaryl VIII. 4-Hydroxy-1 -naphthyl methylcarbamate IX. Unidentified metabolites Rat liver microsomes. Guinea pig liver microsomes. e Guinea pig liver homogenate.

Table Ill.

% of

1

2"

Fluorescence Max., M p

Relative Excitation

1 e 2

Sensitivity Relative to Quinine Sulfate (lnstromental)

450 0.91 100 0 Quinine sulfateh 250 348 51 . o 220 285 3 40 0.78 Carbaryl 465 . . 20.4 I-Naphthol 230 290 465 0.3' 71 . 6 242 330 I-Naphthol, pH 11 . O 5.9 220 285 340 0.69 4-Hydroxy-1-naphthyl 11.4 232 300 480 0.58 methylcarbamate 340 0.86 4.6 5-Hydroxy-1-naphthyl 222 290 455 0.55 28 4 methylcarbarnate 230 296 338 0.73 62.5 285 1-Naphthyl glucuronide 224 93.0 218 278 335 0.61 1-Naphthyl sulfate .ill measurements \iere made a Excitation wave leiigths used for maximum sensitivity. at concentrations of 1 pg./ml. in 0.01M tris buffer, pH 7 . 5 on an Aminco Bowman spectrophotofluorometer equipped with a xenon lamp (Aminco Bowman part 416-992) and l / l 8 1 .O pg./ml. in 0.l.V H ~ S O I . inch emission and excitation slits.

1-naphthyl sulfate. Naphthol-C14 was converted in the rat to two metabolites which eluted off DEAE-cellulose in the identical positions of metabolites G and I. Naphthyl-C'? sulfate chromatographed similarly to metabolite H a n d metabolite G (a Jreaker acid) \vas tentatively identified as 1-naphthyl glucuronide. Metabolism of CarbaryLC'4 by Liver Preparations. Table I1 gives the results for a series of studies involving carbaryl-naphthyl-C'" and various fortified liver preparations. R a t liver microsomes fortified Xiith a hydrogen donor (NADPH2) hydrolyzed carbaryl to yield 1-naphthol and hydroxylated the naphthyl moiety of carbaryl to form 4-hydroxycarbaryl. Other products not identified were produced by the microsomes. R a t and guinea pig liver microsomes fortified Lvith NADPH? and UDPGA converted small quantities of carbaryl-naphthyl-C14 to water-soluble C14 neutrals, metabolite F. and l-naphthy1 glucuronide (metabolite G). I n systems involving microsomes. carbaryl-

n a ~ h t h y 1 - C ' ~and ; CDPG.4, water-soluble C14 neutrals and 1-naphthyl glucuronide \cere formed, indicating that NADPH, is required for the formation of metabolite F. but not for hydrolysis of carbaryl. Since 4-hydroxycarbaryl was produced by microsomes and NADPH?, it was believed to be the product which gave metabolite F in the presence of VDPGA. lt'hen nonlabeled 4-hydroxycarbaryl was incubated \vith guinea pig liver microsomes in the presence of uridine diphosphoglucuronic-C14 acid, a C'"-labeled metabolite was produced having the same elution characteristics as the urinary and microsomal metabolite F. Liver homogenates (rat and guinea pig) fortified with UDPGA formed watersoluble C14 neutrals, 4-hydroxycarbaryl glucuronide, 1-naphthyl glucuronide, and metabolite D from carbaryl-naphthyl(214. Metabolite D was also found as a product of carbaryl-methyl-C14. guinea pig liver microsomes, and UDPGA. A hydrogen donor (NADPHn) was not required in the formation of this metabo-

lite, indicating that the metabolite is formed through a nonoxidative pathway. AY-hydroxycarbaryl, when incubated Lvith guinea pig liver microsomes and uridine diphosphoglu~uronic-C~~ acid, produced 1-naphthyl glucuronide-CI4 and a second metabolite (.Y-hydroxycarbaryl glucuronide-C14). The X-hydroxycarbaryl glucuronide eluted off DEAE-cellulose between metabolite D and 4-hydroxycarbaryl glucuronide. Glucuronide of ,Y-hydroxycarbaryl was not a microsomal meiabolite of carbaryl. 'l'he only major urinary products not formed by the liver preparations \\ere metabolite H and 1-naphthyl sulfate. Homogenates fortifiec! with adenosine-3 'phosphate 5'-phosphosulfate (PAPS) would probably form 1-naphthyl sulfate from carbaryl. Fluorometric Analysis of Carbaryl and Metabolites. Carbaryl does not fluoresce in the common organic solvents investigated. but !vi11 solvate in lvater to produce a distinctive fluorescent peak at 335 mp. 'I'able I11 !gives the excitation and fluorescence maxima for carbaryl, carbaryl derivatives. and metabolites in O.01M tris-HC1 buffcr a t pH 7.5. The conditions reported ,are not necessarily optimal but are those under kvhich chromatogrphic procedures are developed. Figures :\ and 4 are the chromatograms obtained from rat and guinea pig urines. Carbon-14 data from animals receiving carbaryl-naphthyl-CI~ are included in the figures for comparison. I n general. the fluorescence chromatogram \vas identical to the C14 chromatogram even though naturally occurring fluorescent products interfered in the analysis of 4-hydroxycarbaryl glucuronide ( F ) and 1-naphthyl sulfate ( I ) as shown by fluorometric analyis of control urines. At p H 7.5 the metabolites in peak A are weakly fluorescerit or nonfluorescent \vhile a t pH 11 some enhancement of their fluorescence is obtained. Quenching may in part be rcsponsible for their low intensities. The fluorescence characteristics of metabolite B are unknown ( p H 7 . 5 o r 11). MetabolitesCandDdo not fluoresce a t pH 7.5. However, after standing a t pH 11 overnight they exhibited the fluorescent properties of 1naphthol. For unknown reasons, the amount of 1-naphthol detected was subject to consideratile variation. -Vmethyl and AV-acetylcarbaryl (synthetic derivatives) were examined under similar conditions. .Y-.4cetyl carbaryl fluoresces only after hydrolysis to 1-naphthol ( p H 11) while .j.-methy-l carbaryl fluoresces at pH 7.5 and 11. Carbaryl substitutions which produce a change in the hydration influecce on the ring are probably responsiblr for the loss of fluorescence. T h e glucuronide of Shydroxycarbaryl wea.kly fluoresces (I/Z the intensity of 1-naphthyl glucuronide) a t pH 7.5 (335 mp) and hydrolyzes a t a

G

3

1

0

1

80

1

160 240

1

1

320

400

I

1

480

560 640

720

800 880 960 1040 1120

Volume of Eluate (ml.)

Figure 3. Fluorometric and C1* analysis of carbaryl-naphthyl-Cli metabolites present in rat urine after elution from DEAE-cellulose

-

Cl4 analysis Fluorometric analysis Fluorometric analysis of natural products appearing in control urine Gradient elution program: I. 0.01M tris-HCI buffer, p H 7.5, to 0.05M tris-HCI buffer, p H 7.5 II. 0.05M tris-HCI buffer, p H 7.5, to 0.1M tris-HCI buffer, p H 7.5

-__ --

28

t

316

G I!

f 20

e B

-Is f

Y

C

I

z

-" c

-6

3

0

-4

E

-2 0

80

160 240

320

400

480

560 640

720

800 880 960 1040 ti20

Volume of Eluate (mi.)

-11-nFigure 4. Fluorometric and C14 analysis of carbaryl-naphthyl-C14metabolites present in guinea pig urine after elution from DEAE-cellulose

___

C14 analysis Fluorometric analysis Fluorometric analysis of natural products appearing in control urine Gradient elution program: I. 0.01M tris-HCI buffer, p H 7.5, to 0.05M tris-HCI buffer, p H 7.5 II. 0.05M tris-HCI buffer, p H 7.5, to 0.1M tris-HCi buffer, p H 7.5

--

p H of 11 to give 1-naphthol as determined by thin-layer chromatography and fluorescence analysis. Metabolite E chromatographs in the approximate position of the glucuronide of ,\--hydroxycarbaryl, but unlike this glucuronide, the fluorescence of metabolite E is not enhanced at a pH of 11 (465 mp). The identity of metabolite E is at present unknown. T h e glucuronide of 4-hydroxycarbaryl ( F ) fluoresces (335 mp) a t p H 7.5, but does not give a fluorescence maxima a t 465 mp for 1-naphthol when VOL.

hydrolyzed (pH 11). Metabolite F probably hydrolyzes to give 4 hyd oxy-lnaphthyl glucuronide or 1.4-naphthoquinone. At p H 7.5, 1-naphthyl glucuronide fluoresces strongly (335 mp) while no fluorescence maxima for 1-naphthol can be seen a t p H 11. Saphthyl glucuronide (Bios Laboratories) cochromatographed on DEAE-cellulose Ivith metabolite G, as was shown by an increase in the fluorescence of this peak, thus verifying the tentative identity of this metabolite by chromatography as well as fluorescence. Metabo-

1 3 , N O . 6, N 0 V . - D E C .

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lite H; containing all three labels! and 1naphthyl sulfate fluoresce strongly a t p H of 7.5 (335 mp). Because metabolite H chromatographs in the position of a urinary metabolite of 4-hydroxycarbaryl, it is believed to be the sulfate of 4-hydroxycarbaryl. The order and position of elution of metabolite H as a sulfate of 4hydroxycarbaryl is consistent with the facts presented for 4-hydroxycarbaryl glucuronide, 1-naphthyl glucuronide. and 1-naphthyl sulfate. The microsomal metabolites of naphthyl-CIJ and methyl-C14 carbaryl were examined by fluorescence after chromatography on DEAE-cellulose. The microsomal metabolites exhibited the same fluorescent properties as their counterparts in urine. Fluorescence analysis clearly indicated the correct order of elution of 4-h>-drox)-carbarylglucuronide and 1-naphthyl glucuronide when used in combination ivith carbaryl-methyl-C". The glucuronides were detected by fluorescence, Ivhile C14indicated that the first peak was 4-hydroxycarbaryl glucuronide and not 1-naphthyl glucuronide. Table I11 gives the fluorescence intensity of 1-naphthyl glucuronide and sulfate a t 1 fig. per ml. and p H 7.5 relative to quinine sulfate (1 fig. per ml.) in 0.1.V H2S04. Figure 5 depicts the chromatogram obtained with urine specimens from men exposed to carbaryl dust during normal packaging operations. Control urines were obtained 72 hours after exposure. The only detectable metabolites present were 1-naphthyl glucuronide and sulfate. The concentration of 1-naphthyl glucuronide and sulfate appearing in the urine was estimated to be 25 and 5 fig. per ml.. respectively.

!O Volume of Eluate (mi.)

Figure 5. Fluorometric analysis of carbaryl metabolites present in urine of men exposed to carbaryl dust after elution from DEAE-cellulose analysis -- _-- Fluorometric Fluorometric analysis of natural products appearing in control urine Gradient elution program I. 0.01M tris-HCI buffer, p H 7.5, to 0.05M tris-HCi buffer, p H 7.5 II. 0.05M tris-HCI buffer, p H 7.5, to 0.1M tris-HCI buffer, p H 7.5

t----~

Hydrolysis

?

(GI

I

0-C-NHCH3

0-Glucuronide

-

0-Glucuronide

O-k=N-CH3

PH 7.5,

Fi

P

3

0-C-N 'Giucuronide

("ye) Temp.

(Dl

Discussion

(E)

Hydroiylation

Carbaryl is readily absorbed from the gastrointestinal tract and excreted. After 7 days the only detectable C" residue5 present in the rat were from carbaryl-merhyl-C1?. Since neither naphthyl-CI4 or carbonyl-C14 residues could be detected, only the methyl moiety is incorporated in tissue (2 to 3%). Liberated naphthol is readily conjugated and excreted. Lvhile the liberated carbonyl group is disposed of as respiratory P O2. Carbaryl is metabolized in the r a t and guinea pig to a series of eight or more \vater-soluble compounds. Forty-seven to 577, of the metabolites excreted possess the intact C-0-C(0)N-C structure, indicating that a nonhydrolytic pathway exists for carbaryl. The glucuronide of 4-hydroxycarbaryl ( F , 10 to 15%) and metabolite D (12 to 267,) are the major metabolites in this group. Although the exact nature of metabolite D is unknown, it chromatographs on DEAE-cellulose similarly to glucuronicC14 acid and 2-ethylhexanoyl-CI4 glucuronide (77), and is believed to be

542

16 -

J. A G R . F O O D C H E M .

I

. 0 S03H

(H)

P

0-C-NHCH3

@

0-Glucuronide "\

Figure 6. Metabolic path for carbaryl in the rat and guinea pig a n 0-glucuronide of carbaryl (Figure 6) through the enol form. Carbaryl 0glucuronide (1-naphthyl methylimidocarbonate 0-glucuronide) represents the enol form of the carbamate. T h e observed conversion of metabolite D to B may be explained on the basis of the known ( 6 ) irreversible rearrangement of imidocarbonates to the corresponding ,V-substituted carbamates. Metabolite B is believed to be an .J--glu-

curonide of carbaryl (1-naphthyl methylcarbamate AV - glucuronide). Bartley ( 7 ) has successl'ully synthesized 1-naphthyl ethyl ,V-methyl imidocarbonate (carbaryl 0-ethyl) to substantiate the formation of imidocarbonates of carbaryl. This tentative assignment is supported by the difference in the fluorescent properties of 4-hydroxycarbaryl glucuronide and ,V-hydroxycarbaryl glucuronide. A glucuronide of carbaryl-

i.e. 4-hydroxycarbaryl glucuronideconjugated through the naphthyl moiety fluoresces at pH 7.5 (335 mp) and is nonfluorescent at pH 11 (465 mp)> while metabolite D (carbaryl 0-glucuronide) fiuoresces a t pH 11 (465 mp), but is nonfluorescent at pH 7.i;. Conjugation of carbaryl through the .\-hydroxy group produces a molecule that has fluorescent properties similar to carbaryl, while metabolite D has flu'xescent properties similar to .Y-acerylcarbaryl. Metabolite C displays fluorescent properties simiIsr to D and .\--acet!;lcarbaryl. At the present time the iden:ity of metabolite C is unknown. Thirty-nine to 447;, of the administered carbaryl \cas hydrolyzed and the liberated 1 -naphrhol conjugated Lcith glucuronic and sulfuric acids. Fluoromerric and chromatographic analysis of urines obtained from men exposed to carbaryl dust during packaging operations yielded addition,al evidence for conjugation after hydrolysis. Fluorescence was found to be useful during radioactive studies in confirming the presence of the naphthyl moiety by

direct (4-hydroxycarbaryl glucuronide, naphthyl glucuronide, 4-hydroxycarbaryl sulfate, naphthyl sulfate) or indirect (carbaryl 0-glucuronide) analysis. Fluorescence analysis combined with established chromatographic procedure made possible the identification of the t\\o principal metabolites of carbaryl in man. Acknowledgment 'Phe authors thank Sarah J . Kozbelt and Jane ;21. Eldridge for their skilled technical assistance. Literature Cited (1) Bartle)-. \\'-. J.. Union Carbide Olefins Division. South Charleston. IV. \-a,>unpublished data. ( 2 ) Bruno. G. A , . Christian, J. E.. -4nnl. Chem. 33, 1216 (1961). (3) Carpenter. C . P.. I\-ei13 C. S..Palm. P. E.. Woodside. hl. T V . . Nair. J. H.. 111. Smvth. H. F.. .Jr.. J . ;ICR. FOOD CHEM.9, 30 (1961). (4) Casida. J. E.. Rudintion Rndioisotopes ..ip/,d. Insrct.r .IgI. Importanrt. Proc.

Simp.. .-ithem. 1963, pp. 223-239. (5) Dorough. H. \\'.. Casida. J. E.: .J. .AGR. FOODCHEM. 12, 294 (1964). (6) Feigenbaum. J.. Neubrrg. C. .A,. J . .4m. Chem. SOG. 63, 3529 (1941). ( 7 ) Harley-hlason. J.. .\-rctui-cj 155, 515 (1945). ( 8 ) Jeffav. H.. ..\lvarrz. J.. .Ana/. Chrm. 33, 612 (1961). (9) Kamphausen. H. A , . Chrm. Ind. 1962, u. 816. (16) Kelly, R. G.. Peers. E. .A,. Gordon. S.. Buyske, D . A , . *.inn/. Biochrm. 2, 267 (1961). i l l ) Knaak. J. B.. Mellon Instirute. Pittsburgh, Pa.. unpublished data. (12) Khrishna. J. G . . Dorough. H. IV.. Casida. J. E.. J. AGR.FOODCHEM.10, 462 (1962). Rodegker, \V...Inul. (13) Sheppard, H.. Biochem. 4,246 (1962). (14) Skraba. T i . J.. Young. F. G.. J. A G R . FOODCHEM.7, 612 (19591. ( 1 5 ) Smith, E. R.. Breuer. H.. Biochem. J . 88, 168 (1963). (16) Terriere. L. C . . Boose. R . B.. Roubal. T.V. T.. Zbid..79, 620 (1961).

R E S I D U E S I N CNTRUS M.

E. GETZENDANER, W. GARNER, and P. W. MILLER

2,2-Dichloropropionic Acid Residues in Citrus Fruit from Florida Following Applicatiotms of the Herbicide

1.

Bioproducts Department and Analytical Laboratories, The Dow Chemical Co., Midland, Mich.

Dalapon residues in citrus fruits from Florida following a variety of Dowpon applications ranged from 0 to 1 1 p.p.m. The recovery of added dalapon was 90% over the range of 0.2 to 20 p.p.m. The residual herbicide in a sample appeared to be related to several factors inchding the actual amount of chemical applied. A maximum residue of 5 p.p.m. may result from treatments that are recommended on the label. A study related to time between application and harvest indicates that the greatest residue in fruit i s found at the time of a flush of growth of the trees. No loss of chemical was caused b y a heat treatment simulating commercial pulp drying. Residues from ditch-bank treatments were 0.2 p.p.m. and lower.

Tg

of many species of rass in areas Lvhere citrus fruit is gro\vn causes a ver) difficult control problem. Bermuda ( c ~ n o d o n dactjion) , bahia (Pnrpciiitm notntum), para (Panicum purpuroscpru). guinea iPanicurn matzmum), maidencane fPunicuni henzitomon): and Johnson (Sorghun7 hnirpenre) grasses are among the principal offenders. competing xvith the citrus trees for \vater and nutrients. Uncontrolled grass growth makes other pest control difficult, and adds greatly to grove maintenance problems. By the proper use of Dowpon ('The Dow Chemical C o . ) containing HI; PREYALESCE

857, of the sodium salt of dalapon (trade-mark of T h e Do\c Chemical Co. abroad for 2.2-dichloropropionic acid), it is possible to control most grasses safely with a minimum of labor. This srudy Jvas undertaken to determine the residue of dalapon in citrus fruit from areas treated Lvith DoJtpon for control of grasses. T h e data presented here were used in a petition to the U. S. Food and Drug Administration to establish a tolerance for dalapon in citrus fruits from Florida ( 7 ) . A s a result of this \cork: Doi\-pon is accepted for use in commercial VOL.

orchards in Florida lvith a legal tolerancc of 5 p.p.m. of dalapon in grapfruit, limes, tangerines, and oranges. Experimental .Applications were made as indicated in Tables 11: 111, and IV. I n general. each experiment consisted of treatment of plots of 2 to 6 trees replicared at least twice. A sample \vas taken by random selection of 4 to 10 oranges from each tree, \chich were combined into a single sample. \Vhen duplicate samples Xvere collecred, the process \vas repeated. 'The samples \cere shipped to the

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